A position measurement system for measuring displacement of an observation station viewed from a reference station by receiving radio waves from satellites by these stations, and performing relative position measurement between the stations, having: a short period displacement measurement section for measuring a short period displacement component in each of the stations through independent position measurement; a relative position computing section for performing relative position measurement between said stations; a long period position computing section for inputting a short period displacement component measured by the short period displacement measurement section, a relative position determined by the relative position computing section and an absolute position from the reference station, and determining the absolute position including a long period displacement component by removing the short period displacement component measured by each of the stations; and a radio communication device installed on each of the stations, for transmitting/receiving data to/from another station.
|
1. A relative position measurement system for measuring displacement of an observation station viewed from a reference station by receiving radio waves from satellites by the reference station and the observation station and performing relative position measurement between said stations, comprising:
a short period displacement measurement section for measuring a short period displacement component in each of said stations through independent position measurement;
a relative position computing section for performing relative position measurement between said stations;
a long period position computing section for inputting a short period displacement component measured by said short period displacement measurement section and a relative position determined by said relative position computing section, and determining a relative position including a long period displacement component by removing the short period displacement component from the relative position; and
a radio communication device installed in each of said stations, for transmitting/receiving data to/from another station.
2. The relative position measurement system using satellites according to
3. The relative position measurement system using satellites according to
4. The relative position measurement system using satellites according to
5. The relative position measurement system using satellites according to
6. The relative position measurement system using satellites according to
said monitoring facility performs relative position measurement between said stations, and determines the relative position of the observation station with respect to the reference station by removing the short period displacement component measured by each station.
|
The present invention relates to a relative position measurement system for detecting displacement by relative position measurement using radio waves from a plurality of satellites.
As a satellite position measurement technology for receiving and analyzing radio waves from a plurality of satellites and detecting a position of a receiver (hereafter called “mobile station” or “observation station”), a single position measurement system for measuring position by a sole mobile station even if the measurement error is large, and a relative position measurement system for accurately determining the position of a mobile station using the correction data from a reference station of which position is known, are available.
In the relative position measurement system, the position measurement accuracy is restricted by the linear distance between receivers, which is the so-called “base length”.
For example, in the case of a relative position measurement system which measures position independently using the C/A code of GPS (Global Positioning System) and corrects the measured data using correction data, the limit of the base length, when an error due to the ionosphere and atmosphere is approximately the same for each receiver, is about 100 km or less, and since an error can be offset within this range, an improvement of position measurement accuracy in the relative position measurement system can be expected.
On the other hand, in the case of a system which analyzes the base line using a carrier phase so as to improve the position measurement accuracy, the limit of the base line is short, about 10 km or less, but the position measurement accuracy improves dramatically since a carrier phase, which is sufficiently shorter than the C/A code, is used. [See the new edition of GPS—Precision Positioning System by Satellites (issued by the Japan Survey Association).]
In the case of the relative position measurement system mentioned above, however, the relative position of a mobile station, with respect to the reference station, can be measured accurately, but if the reference station is displaced, the relative position cannot be measured accurately.
For example, if the reference station is shaking due to an earthquake, the reference station is displaced, so that the position of the remote mobile station of which relative position is measured includes the displacement component, so this relative position measurement system cannot perform the measurement of displacement sufficiently when a disaster occurs.
An advantage of the present invention is a relative position measurement system using satellites that can measure the relative position measurement accurately even if one station is displaced when relative position measurement is performed.
A relative position measurement system using satellites of the present invention is a system for measuring the displacement of an observation station viewed from a reference station by receiving radio waves from satellites by the reference station and observation station, and performing relative position measurement between these stations, comprising: a short period displacement measurement section for measuring a short period displacement component in each of the stations by independent position measurement; a relative position computing section for performing relative position measurement between these stations; a long period position computing section for inputting a short period displacement component measured by the short period displacement measurement section and a relative position determined by the relative position computing section, and determining a relative position including a long period displacement component by removing the short period component from the relative position; and a radio communication device installed on each of the stations, for transmitting/receiving data to/from another station.
In the relative position measurement system, it is preferable that the reference station and the observation station are installed on floating bodies floating on a sea surface.
In the relative position measurement system, it is preferable that the reference station and the observation station are installed on floating bodies floating on a sea surface, and the short period displacement component, measured by the short period displacement measurement section, is a displacement component generated by waves.
In the relative position measurement system, it is preferable that a plurality of the observation stations are provided, and each observation station is disposed so that base lines connecting each observation station and the reference station mutually cross at a predetermined angle.
In the relative position measurement system, it is preferable that the reference station is integrated with and installed on ground, and the short period displacement component, that is measured by the short period displacement measurement section provided in the reference station, is a displacement component generated by an earthquake.
It is preferable that the relative position measurement system further comprises a monitoring facility for performing centralized control for satellite data for the position measurement received by each station and a short period displacement component measured by each station, wherein the monitoring facility performs relative position measurement between the stations, and determines the relative position of the observation station with respect to the reference station by removing the short period displacement component measured by each station.
According to the relative position measurement system, the relative position of the mobile station with respect to the reference station is measured, the short period displacement measurement section is installed in each station, and the short period displacement component is accurately determined through independent position measurement, so even if the reference station is displaced during a short period, for example, the relative position of the mobile station can be accurately measured by removing the short period displacement component.
Now the relative position measurement system using satellites according to the present invention will be described.
In the present embodiment, a case of applying a real-time kinematic system using GPS (Global Positioning System) satellites as a relative position measurement system, and measuring a position of a floating body, which is moored on a sea surface for detecting a displacement of the sea level (this can be the water level of a lake or similar body of water) as the position measurement target, will be described.
The relative position measurement system using satellites according to the present embodiment will now be described with reference to
As shown in
The reference station 1, as shown in
As shown in
Now the position measurement computing device 23 installed in the mobile station 3 will be described in detail.
As shown in
Needless to say, transmission data created by the transmission data creation section 35 is sent to the reference station 1 via the transmitter 22a. Among the satellite data for position measurement, the orbit information, elevation angle and azimuth, for example, are received by two stations which perform relative position measurement respectively, and the elevation angle and azimuth are hardly different between the two stations, so if the data is obtained only by the GPS receiver 11 or 21 of one of the stations, then the data may be sent to the other [station] and used. The data used for relative position measurement is acquired from the data storage section 31 when necessary.
Now a method for determining the long period absolute position including the long period displacement component in the relative position measurement system, will be described with reference to the flow chart in
First the short period displacement measurement sections 12 and 33 of the reference station 1 on land and each mobile station 3 determine the respective short period displacement component at high precision based on the satellite data for position measurement (step 1).
Then the satellite data for position measurement, temporary coordinates and absolute position of the reference station 1, and the reference station short period displacement component are sent to each mobile station 3 on the sea surface (step 2).
Then in the relative position computing section 32 of each mobile station 3, the relative position with respect to the temporary coordinates of the reference station 1 is determined by the relative position measurement with the reference station 1 based on the RTK system (step 3).
Then in the long period position computing section 34 of each mobile station 3, the absolute position of each mobile station 3, including the long period displacement component, is determined by using the absolute position (absolute coordinates) of the reference station 1, reference station short period displacement component and mobile station short period displacement component, that is, by removing the reference station short period displacement component and mobile station short period displacement component from the relative position (relative displacement) between these stations (step 4).
Then the absolute position of each mobile station 3, including the long period displacement component, is sent via radio waves to the reference station 1 (step 5).
In other words, once the absolute position of each mobile station 3, where the short period displacement component is removed, is determined, the position of long period displacement, where the displacement component due to waves on the sea surface is removed, can be measured, and by determining the difference of the measurement position at a previous time and the measurement position at this time, the long period displacement component can be measured.
For example, if the position of each mobile station 3 suddenly changes (displacement from the measured value at previous time is greater than normal), this could refer to the case where a tsunami is generated by an earthquake, and here the reference station 1 itself fluctuates, by measuring this fluctuation as the short period displacement component and removing this short period displacement component, the tsunami can be measured accurately as the long period displacement component.
In order to detect only the displaced position in a long period or only the long period displacement component, like the case of a tsunami, relative positions are used, and the absolute position does not always need to be determined.
Here a method of measuring displacement through independent position measurement, executed in the short period displacement measurement sections 12 and 33 at high precision (also called the “high precision variation detection method”, hereafter called the “PVD method”), will be described in brief.
The PVD method was disclosed in a Japanese Patent Publication (Japanese Patent Application Laid-Open No. 2001-147263), and is a method for measuring displacement through an independent position measurement method using GPS satellites at high precision.
With this PVD method, which uses a carrier phase of which wavelength is much shorter than the C/A code, the short period displacement component (displacement quantity) can be measured with precision equivalent to the level of displacement measured by position measurement based on a real-time kinematic method, which is one relative position measurement method that measures using a carrier phase, and a very accurate measurement result can be acquired even if it is an independent position measurement.
Now the general configuration of the short period displacement measurement sections 12 and 33 will be described.
As
The distance measurement section 51 counts the waves of the carrier of the radio waves from a predetermined satellite which are received by the GPS receiver, and measures the distance (carrier phase) between the predetermined satellite and the GPS receiver (to be precise, this is a distance to the antenna, but a distance to the GPS receiver is used here for this description). (The integer bias used for determining the carrier phase is determined by using four satellites.)
The displacement detection section 52 is further comprised of a moving average processing section 61 for inputting the measurement distance data obtained by the distance measurement section 51 and determining the moving averages of several tens of sampling points, so as to determine the distance data corresponding to the orbit distance of the satellite, and a displacement computing section 62 for determining the displacement of the GPS receiver with respect to the satellite by subtracting the equalized distance data, which is the orbit distance of the satellite, acquired by the moving average processing section 61, from the original measurement distance data.
In the disturbance influence removal section 53, variants due to the influence of wind and waves are removed by allowing the data to pass through the band pass filter, which cuts the frequency band components of the wind and waves.
In the displacement computing section 54, according to each displacement obtained based on the measured distance data from three satellites after disturbance is removed, and according to the azimuth and elevation angle of each satellite, three linear equations, where three-dimensional coordinates of the GPS receiver are unknowns, are created, and the displacement components (X, Y, Z) of the GPS receiver in three-dimensional coordinates are determined by solving the simultaneous linear equations with these three unknowns.
In other words, the short period displacement components are generated by the waves received by the floating body having the GPS receiver, which is a mobile station, and are measured by: the distance measurement section 51 measuring the distance between the GPS receiver and the GPS satellite; the displacement detection section 52 performing moving average processing on the measurement distance data obtained by the distance measurement section 51, removing the distance data corresponding to the distance to the satellite orbit and determining the displacement of the GPS receiver; the disturbance influence removal section 53 removing the noise generated by the wind and waves; the displacement computing section 54 determining at least three linear equations of which the unknowns are the three-dimensional coordinates of the GPS receiver, based on the displacement with respect to the three GPS satellites, and the azimuth and elevation angle of each GPS satellite, and determining the displacement components on the three-dimensional coordinates of the GPS receiver by solving the above mentioned three simultaneous equations.
In this way, the relative position of the mobile station, with respect to the reference station, is measured based on the RTK system, and the short period displacement component is accurately determined through an independent position measurement by disposing the short period displacement measurement section in each station, therefore even if the reference station fluctuates (is displaced) in a short period, the short period displacement component can be removed, and the relative position (or absolute position) of the mobile station can be determined accurately.
In the present embodiment, the reference station is installed on land, but the reference station 1 may be installed on a floating body 2 on the sea surface, as shown in
In this case, the differences from
By disposing the reference station and the mobile stations (observation stations) in this way in a sea area which is distant from land (e.g. a position exceeding the base line limit length of the kinematic system) with a mutual space that is the base line limit length of the kinematic system or less, a tsunami, for example, can be measured accurately offshore, which is distant from land exceeding the base line limit length. (Needless to say, the measurement data obtained at each station is sent to a distant monitoring facility on land via radio.) In other words, the approach of a tsunami can be known in a sea area distant from the coast line, so damage by a tsunami can be minimized.
In the description of the above embodiment, the position measurement computing device is disposed in each mobile station, and the absolute position (or relative position) of the respective mobile stations is determined, but each data may be sent to a monitoring facility (which could also serve as a reference station) on land along with the identification number of the station by a transmitter, so as to be centrally managed.
It is also acceptable that the position measurement computing device is disposed in the reference station and at the same time, the satellite data for position measurement measured by each mobile station is sent to the reference station and stored there, and the absolute position (or relative position) of each mobile station, based on the long period displacement component, is determined by the position measurement computing device of the reference station.
Now the general configuration of the reference station will be described in brief.
As
In this way, the satellite data for position measurement is sent from each mobile station to the reference station, this data is stored in the reference station, and using this data, the reference position (or absolute position) of each mobile station, including the long period displacement component, is determined by the relative position computing section.
If the reference station measures the relative position, the configuration of the mobile station becomes like
In the above embodiment, the satellite data for position measurement is stored in the reference station, but this data needs not always be stored and may sequentially be computed if the data transmission timing of each station is set to be shifted.
In the description of the above embodiment, data is transmitted/received between stations via the radio communication device, but if communication by ground waves cannot be performed due to visual limitation, data can be transmitted/received via a communication satellite.
Also in the description of the above embodiment, mobile stations are disposed on the sea surface to measure tsunami, but both the reference station and mobile stations may be disposed on land and used as a seismograph.
Also in the above embodiment, satellite measurement based on GPS was used as an example, but the present invention can also be applied to a satellite position measurement system based on the same principle, or which will be available in the future.
According to the relative position measurement system of the present invention, relative position measurement is performed between a reference station and a mobile station using a real-time kinematic system, and each station has a short period displacement measurement section which can measure the short period displacement component through an independent position measurement at high precision, so if the mobile station is installed on a floating body on a sea surface, for example, a long period displacement component, such as a tsunami when an earthquake occurred, can be measured by the mobile station by removing the displacement component of waves, which is a short period displacement component, from the displacement of the mobile station, and therefore damage caused by a tsunami can be minimized. In some cases, this relative position measurement system can also be used as a seismograph.
Fujita, Takashi, Terada, Yukihiro, Ito, Keiji, Abe, Takenori
Patent | Priority | Assignee | Title |
8604972, | Sep 25 2008 | Hitachi Zosen Corporation | Position measuring device and position measuring method by means of GPS |
Patent | Priority | Assignee | Title |
6366854, | Nov 24 1999 | Hitachi Zosen Corporation | Method and apparatus for measuring displacement of object using GPS |
6434509, | Mar 31 2000 | Hitachi Zosen Corporation | Method and apparatus for measuring displacement of object using GPS |
JP11063984, | |||
JP2001027665, | |||
JP2001147263, | |||
JP2001174259, | |||
JP2001281323, | |||
JP2004239841, |
Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Nov 10 2004 | Hitachi Zosen Corporation | (assignment on the face of the patent) | / | |||
Apr 18 2007 | TERADA, YUKIHIRO | Hitachi Zosen Corporation | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 019264 | /0547 | |
Apr 18 2007 | ITO, KEIJI | Hitachi Zosen Corporation | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 019264 | /0547 | |
Apr 18 2007 | ABE, TAKENORI | Hitachi Zosen Corporation | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 019264 | /0547 | |
Apr 18 2007 | FUJITA, TAKASHI | Hitachi Zosen Corporation | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 019264 | /0547 |
Date | Maintenance Fee Events |
May 11 2012 | M1551: Payment of Maintenance Fee, 4th Year, Large Entity. |
Jun 24 2016 | REM: Maintenance Fee Reminder Mailed. |
Nov 11 2016 | EXP: Patent Expired for Failure to Pay Maintenance Fees. |
Date | Maintenance Schedule |
Nov 11 2011 | 4 years fee payment window open |
May 11 2012 | 6 months grace period start (w surcharge) |
Nov 11 2012 | patent expiry (for year 4) |
Nov 11 2014 | 2 years to revive unintentionally abandoned end. (for year 4) |
Nov 11 2015 | 8 years fee payment window open |
May 11 2016 | 6 months grace period start (w surcharge) |
Nov 11 2016 | patent expiry (for year 8) |
Nov 11 2018 | 2 years to revive unintentionally abandoned end. (for year 8) |
Nov 11 2019 | 12 years fee payment window open |
May 11 2020 | 6 months grace period start (w surcharge) |
Nov 11 2020 | patent expiry (for year 12) |
Nov 11 2022 | 2 years to revive unintentionally abandoned end. (for year 12) |